PHOTOVOLTAIC MODULE RECYCLING: THERMAL TREATMENT TO DEGRADE POLYMERS AND CONCENTRATE VALUABLE METALS

IF 1.2 Q4 ENGINEERING, ENVIRONMENTAL Detritus Pub Date : 2021-09-30 DOI:10.31025/2611-4135/2021.15119

P. S. S. Camargo, A. Domingues, J. Palomero, A. C. Kasper, P. Dias, H. Veit

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引用次数: 3

Abstract

ABSTRACT: This work investigated the thermal treatment to separate and concentrate economically valuable materials from laminates of crystalline silicon photovoltaic modules (i.e., photovoltaic modules without the aluminum frame and the junction box). Chemical characterization of the metal content was performed by X-Ray Fluorescence (XRF). The polymers of the backsheet were also characterized by Fourier Transform Infrared Spectroscopy (FTIR). The influence of the atmosphere (oxidizing and inert) on the decomposition of the backsheet was investigated by Thermogravimetric Analysis (TGA). Moreover, non-comminuted samples were tested for 4 thermal time lengths (30, 60, 90, and 120 min) in the furnace under ambient air. The degradation of the polymers was measured and 3 material fractions were obtained: silicon with silver and residual polymers (SS), glass and copper ribbons. Furthermore, there was no statistical difference between the mass losses of the samples submitted for 90 (13.62 ± 0.02 wt.%) and 120 min at 500 °C (p-value = 0.062). In the SS fraction, silver was 20 times more concentrated than in the ground photovoltaic laminate and 30 times more concentrated than high silver concentration ores. The SS fraction (about 6 wt.%) also presented low copper concentration and a high concentration of lead (hazardous metal). About 79 wt.% glass was obtained, as well as 1% copper ribbons (55.69 ± 6.39% copper, 23.17 ± 7.51% lead, 16.06 ± 2.12% tin). The limitations of the treatment and its environmental impact are discussed, and suggestions for industrial-scale application are given.

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光伏组件回收:热处理降解聚合物和浓缩有价金属

摘要：本工作研究了从晶体硅光伏模块（即没有铝框架和接线盒的光伏模块）的层压板中分离和浓缩具有经济价值的材料的热处理。通过X射线荧光（XRF）对金属含量进行化学表征。还通过傅立叶变换红外光谱（FTIR）对底片的聚合物进行了表征。通过热重分析（TGA）研究了气氛（氧化和惰性）对底片分解的影响。此外，在环境空气下，在炉中对未粉碎的样品进行4个热时间长度（30、60、90和120分钟）的测试。测量了聚合物的降解，获得了3种材料组分：含银的硅和残余聚合物（SS）、玻璃和铜带。此外，在500°C下90（13.62±0.02 wt.%）和120分钟内提交的样品的质量损失之间没有统计学差异（p值=0.062）。在SS部分中，银的浓度是地面光伏层压板的20倍，是高银浓度矿石的30倍。SS部分（约6wt.%）还表现出低铜浓度和高浓度的铅（危险金属）。获得了约79重量%的玻璃，以及1%的铜带（55.69±6.39%的铜，23.17±7.51%的铅，16.06±2.12%的锡）。讨论了处理的局限性及其对环境的影响，并提出了工业化应用的建议。

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